Method for converting electric signals and a converter therefor

ABSTRACT

The invention relates to signal conversion devices to be used for the receiving radio devices. The attained technical result is the detection and conversion of signals in an electrical two-terminal device, a data loss level being minimal. A converting element is supplied with input signals, interaction of the fields of said signals in the converting element material is provided, which interaction is accompanied with the energy interchange resulting in appearance of the efficient electromotive force, and extracted is the converted signal complying with the following ratio:  
           U   ′     ⁡     (   t   )       =         -   γ     ⁢            R   x     ⁢     {       ∑         U   i     ⁡     (   t   )       ·            U   o     ⁡     (   t   )                +         U   o     ⁡     (   t   )       ·          ∑       U   i     ⁡     (   t   )                  }               x   o     ⁢   l           
 
where U&#39;(t) is the efficient electromotive force in the converting element, R x  is Hall coefficient of the converting element conductive material (C/m 3 ); l is length of the converting element along the current direction, (m); x o  is the least one of linear dimensions of the converting element cross-section that is perpendicular to direction of the current flowing therein, (m); γ=τ·ε o ; ε o  is electric constant, ε o   ≈10   −11  C/V·m, τ is dimensionless factor that represents a degree of interrelationship of the fields in a conductive medium; ΣU i (t), where i=l . . . n is the combined voltage of the input convertible signals; Uo(t) is voltage of the input converting signal; at that, the ratio between the physical parameters and geometric parameters of the converting element and the sum of voltages of the input signals is selected with regard to condition  2  γ|R x |U/x o l≧l, where U is sum of voltages of the input signals

The invention relates to radio engineering, in particular it relates to the devices for conversion of signals, and can be suitably used in designing of the receiving radio devices.

Detection and (frequency-) conversion of signals can be implemented using the known electronic devices having the non-linear volt-amper characteristic: two-terminal diodes of all types, or having the non-linear characteristic of the parametric dependence of conductivity on the action effected by an external signal: radio tubes, transistors, field-effect transistors. Thus, for example, a conventional converter in the form of a crystal (semiconductor) diode can be used both in detection and frequency-conversion of signals. However, this converter has such drawbacks as a low transmission coefficient in the detection mode, and a low frequency conversion coefficient in the superheterodyne reception mode.

Drawbacks of the known signal converters are due to their features in respect of the detection and frequency-conversion modes, as separately described below.

A) Signal detection mode. All existing gate-based devices, such as tube diodes, semiconductor diodes have a very low value of

l/

U derivative of l(U) function i.e. that of conductivity in case of small values of signal U acting at their input (FIG. 1 a) and, consequently, a very low transmission coefficient G of circuit R_(d), R_(id) (FIG. 2 a), where R_(d) is diode dynamic resistance determined as

U/

l; R_(id) is load resistance, G=R_(id/R) _(d). When direct voltage E_(o) is applied to circuit R_(d), R_(id) and shifts the operating point (FIGS. 1 b, 2 b), the output signal is proportional to U₂ and has a low value. Whereas noise power P_(n)—due to fluctuations caused by the particle heat motion and produced by any active resistance into the matched, i.e. equal to the resistance load R_(id) in ΔF frequency band—is P _(n) =kTΔF   (1) where k is Boltzmann constant, T is absolute temperature whereat a device is operated, then mean square of the noise voltage across resistance R_(d) can be expressed as: hu 2 _(o)=4k TΔF R _(d)   (2).

Thus, registration of the detected signal across load R_(id) (FIG. 2 a) is possible only when the input signal voltage U_(inp)>e_(n), i.e. when R_(d) has great values, a small signal is not discernible against the noise background.

B) Frequency-conversion mode (superheterodyne reception). In this mode, said known converters for frequency-conversion of signals can be used just owing to non-linearity of their volt-amper characteristic (FIG. 1). If the input signal is the sum of voltages U₁(t)+U₂(t), where U₁(t)=U₁ sin ω _(t)(t), U₂(t)=U₂sin ω ₂(t), when U₂>>U₁, and dependence I(U) is I(t)=k U ₁ ²(t)+2kU ₁(t)U ₂(t)+kU ₂ ²(t)   (4)

Hence, current l(t) comprises components of signals of intermediate frequency l_(int), U _(int)=l_(int)R_(d): U_(int 1)(t)=U _(int 1)sin(ω₂−ω₁)t; U _(int 2)(t)=U _(int 2)sin(ω₂−ω₁)t;   (5)

If U₁(t) is the received signal, U₂(t) is the heterodyne voltage, then according to (4) derivative

I(t)/

U(t)=2k U₂(t), and signal power U₁(t) will be equally distributed between signals U_(int 1), U_(int 2), and that being only during one half-period ω ₁(t), because the second half-period ω ₁(t), when ω₁≈ω₂, is cut off by the diode (FIG. 3).

Thus, even when selection of mode of such converter is optimal, when the value that is inverse to

l(t)/

U(t) represents the matched load of the input circuit in which U₁(t) is transmitted, the power of the converted signal P_(cd1) or P_(cd2) is still four times less than power Pl(t) of the input signal. Ratio P_(cd/P) _(l)=η−conversion ratio; η≦0.25 or −6 dB.

At that, the noise characteristics of the converted signal with respect to the input signal U₁(t)=U_(inp) deteriorate by value of η, P _(cd) /P _(n)=(P _(inp) /P _(n))ω  (6)

and, consequently, the threshold sensitivity of a heterodyne receiver falls.

The above-discussed effect of the thermal noise is not the only interference factor. When an electric field is applied to a semiconductor, the following noises emerge: shot noise, flicker noise (at low frequencies), modulating noise in diodes having a great series resistance for direct current.

In view of the foregoing, the object of the invention is to provide a converter that will be free of said drawbacks intrinsic to the known converters, that will detect and convert signals in an electrical two-terminal device so that the loss level of the data transmitted by such signals will be minimal.

in particular, the object of the invention consists in providing an element in an electric circuit (two-terminal device) that will provide the following advantages: for the signal detection mode—the linear dependence of output voltage on input voltage, and an high transmission coefficient; for the signal frequency-conversion mode—a considerable increase in the conversion ratio; and that will have no other noise effects than the thermal ones.

The technical result to be attained: for the signal detection mode—to provide the linear dependence of output voltage on input voltage, and an high transmission coefficient; and for the frequency-conversion mode—to provide a considerable increase in conversion ration, while maintaining the noise factor at least at the level of the most pertinent prior art.

Said technical result is to be achieved as follows: an electric signal converter comprises a converting element, in particular a two-terminal element made of a conductive material and intended for being supplied with at least two input signals and for extracting a converted signal, whereby the ratio between the physical parameters and geometric parameters of the converting element and the sum of voltages of the input signals satisfies the following condition: 2γ|R _(x) |U/x _(o) l≧I,

where U is sum of voltages of the input signals,

R_(x) is Hall coefficient of a converting element conductive material, (C/m³);

l is length of the converting element along the current direction, (m);

x_(o) the least one of linear dimensions of the converting element cross-section that is perpendicular to direction of the current flowing therein, (m); γ=τ·ε_(o), ε_(o) is electric constant, ε_(o)≈10⁻¹¹ C/V·m, τis dimensionless factor that represents a degree of interrelationship of the fields emerging in a conductive material under action of the input signals and being within the range of 10⁻³÷10⁻².

Further, voltage of at least one of the input signals is considerably greater that that of each of other in put signals.

The converting element can be implemented in the form of a thin film, x_(o) thick, on a dielectric substrate and provided with leads disposed in the plane of said film at distance l, x_(o) and length l, provided with leads connected to ends of the cylinder.

Besides, the converting element can be also implemented in the form of a fine-grained structure having linear dimensions of a grain of the order of x_(o), l provided with leads to provide contact at least with one grain, said fine-grained structure can be disposed on a substrate being one of the leads, the other lead directly contacting with said fine-grained structure material grain and having the contact area whose linear dimensions are of the order of those of the grain.

Further, the converting element can be at least one micro-asperity on the surface of said material, having height l of the micro-asperity and its cross-section size x_(o), and has a lead connected to the micro-asperity apex.

A material having a high value of Hall coefficient is preferably selected as the converting element conductive material.

Said technical result is also to be attained through a method for converting electrical signals, comprising the steps of: providing a converting element in the form of a two-terminal device made of a conductive material, applying to said converting element at least tow input signals; converting the input signals by providing interaction of fields of said signals in the converting element material, which interaction is accompanied with the energy interchange resulting in emergence of an efficient electromotive force of the conversion; and extracting the converted signal that satisfies the following ratio: ${U^{\prime}(t)} = \frac{{- \gamma}{{R_{x}\left\{ {{\sum{{U_{i}(t)} \cdot {{U_{o}(t)}}}} + {{U_{o}(t)} \cdot {{\sum{U_{i}(t)}}}}} \right\}}}}{x_{o}l}$ where U'(t) is the efficient electromotive force across the converting element caused by action of voltages of the input signals, R_(x) is Hall coefficient of the converting element conductive material (C/m³): l is length of the converting element along the current direction, (m); x_(o) is the least one of linear dimensions of the converting element cross-section that is perpendicular to direction of the current flowing therein, (m); γ=τ·ε_(o); ε_(o) is electric constant, ε_(o)≈10⁻¹¹ C/V·m, τ is dimensionless factor that represents a degree of interrelationship of the fields emerging in a conductive medium and is selected within the range of 10⁻³÷10⁻²; Σ U_(i)(t), where i=l . . . n is the combined voltage of the input convertible signals; Uo(t) is voltage of the input converting signal.

at that, the ratio between physical parameters and geometric parameters of the converting element and sum of voltages of the input signals is selected according to the following condition: 2γ|R _(x) |U/x _(o) l≧I, where U is voltage across the converting element, equal to sum of voltages of the input signals.

Voltage Uo(t) of the input converting signal is preferably selected to be significantly greater than voltage of each of the input convertible signals, and in such case power of the converted signal is provided by the power take-off from the input converting signal, and extraction of the converted signal is done by an intermediate frequency filter or using a full-wave circuit through compensation of the combined voltage Σ U_(i)(t) of the input convertible signals at the electric neutral point of said circuit.

To obtain the converted signal having a low value of the intermediate frequency as the input converting signal, a harmonic signal Uo(t) having a frequency proximate to half the frequency of the convertible input signal is selected. Further, as the input converting signal Uo(t), voltage of a direct current source can be selected; thereby conversion of the input signals is carried out in the form of the linear detection.

In devising the invention, the author assumed that said objective could be achieved, in principle, using only the linear two-terminal devices—resistors, i.e. a converter according to the invention must have, at least in a certain range of the voltages acting thereon, the linear volt-amper characteristic. At that, in the absence of the non-linear dependence of l(U), the effect of signal conversion may be obtained only in the case if in the linear two-terminal device structure provided is such interaction of electromagnetic fields associated with the input signals that will result in appearance of the electromotive force of interrelationship of signals. Thus, the author has ascertained that the process of signal conversion in a linear two-terminal device is provided in the presence of the energy interchange between the fields of the signals acting on said device. The effect of such electrodynamic mode is the negative slope of dependence U_(int)(l), i.e.

U_(int)/

l<0, which indicates the energy take-off.

As a result of the carried-out theoretical investigations and experiments the author has ascertained that in a conductor, in particular a homogeneous and isotropic conductor, being subjected to sum of external voltages, electromotive force of U'(t) interrelationship appears and is expressed analytically as follows: $\begin{matrix} {{U^{\prime}(t)} = \frac{{- \gamma}{{R_{x}\left\{ {{\sum{{U_{i}(t)} \cdot {{U_{o}(t)}}}} + {{U_{o}(t)} \cdot {{\sum{U_{i}(t)}}}}} \right\}}}}{x_{o}l}} & (7) \end{matrix}$ where U'(t) is the efficient electromotive force developed in the converting element, caused by voltages of the input signals, R_(x) is Hall coefficient of the converting element conductive material (C/m₃); l is length of the converting element along the current direction, (m); x_(o) is the least one of linear dimensions of the converting element cross-section that is perpendicular to direction of the current flowing therein, (m); γ=τ·ε_(o); ε_(o) is electric constant ε_(o)≈10⁻¹¹ C/V·m, τ is dimensionless factor that represents a degree of interrelationship of the fields emerging in a conductive medium, being within the range of 10⁻³÷10⁻²; Σ U_(i)(t), where i=l . . . n is the combined voltage of the input convertible signals; Uo(t) is voltage of the input converting signal. dr

The invention is explained by examples of its embodiment shown in figures, wherein

FIGS. 1 a, 1 b—volt-amper characteristics of the prior art electric signal converters;

FIGS. 2 a, 2 b—circuits that comprise the prior art electric converters;

FIGS. 3-6—versions of implementation of a converting element of the electric signal conversions device according to the invention;

FIGS. 7, 8—circuits that comprise the electric signal conversion device according to the invention;

FIGS. 9-12—diagrams that describe operation of the electric signal conversion device according to the invention.

FIGS. 3-6 show examples of possible versions for embodying converting element 1 of the converter according to the invention. As FIG. 3 illustrates, converting element 1 is thin-film conductive coating 2, for example applied upon insulating substrate 3. Dimensions x_(o), l, where l is length of converting element 1 along the current direction; x_(o) is linear dimension of cross-section of converting element 1, which cross-section is perpendicular to the current direction, are selected from ratio (7). Dimension α defines a predetermined value of resistance of the converting element. Leads of the converter in the form of contact pads 4, whose resistance is negligible as compared with value of resistance of thin-film coating 2, provide the possibility to couple converting element 1 into a circuit. As the material of thin-film coating 2, any conductor having an high value of Hall coefficient can be selected, e.g.

1) metals: Fe (R _(x)≈10⁻⁹ C/m³), Ni (R _(x)≈1.5·10⁻⁹ C/m³), Bi (R _(x)≈10⁻⁷ C/m³), Sb (R _(x)≈10⁻⁸ C/m³), Gd (R _(x)≈3·10⁻⁷ C/m³),

2) alloys: MnSb and CrTe (R_(x)≈10⁻⁶ C/m³),

3) semiconductor materials: Si, Ge, etc, with admixtures that provide predetermined values of conductivity of a material and Hall coefficient, under the condition that the technique used for applying the contact pads excludes formation of p-n or n-p transitions therebetween and the element 1 material,

4) ferrites of diverse types.

FIG. 4 shows the embodiment of converting element 1 implemented in the form of cylindrical conductor 5 that is melted-in (or introduced by another method) into the opening, with radius r_(o), in insulating body 3 (of the substrate) and has l length (length (length of converting element 1). Contact pads (leads) 4 are applied on the end faces of substrate 3. FIG. 5 illustrates the third possible embodiment of converting element 1 in the form of a fine-grained structure having grain 6 linear dimensions of the order of x_(o), l, provided with leads 4 to ensure contact with at least one grain 6.

FIG. 6 illustrates the fourth possible embodiment of converting element 1 in the form of at least one micro-asperity 7 on the surface of a conductive material, having height l, cross-section x_(o), and said element has lead 4 connected to apex of micro-asperity 6.

FIGS. 7, 8 represent versions of circuits comprising the electric signal converter according to the invention.

According to FIG. 7: electric signal converter 8 is coupled into a full-wave conversion circuit that includes transformer 9 that is a low-, or high-frequency transformer, depending on the frequency of the convertible signals, and having midpoint 10 of secondary winding 11. Output voltage of secondary winding 11 acts upon two in-series connected elements converter 8 and balancing resistor 12 whose resistance is ρ, that is the resistance value of converter 8. The node of connection of said elements is point 13 of the electric neutral point, for the voltage developed across secondary winding 11. To point 13 connected is resistor R_(id)—load 14, and controllable direct current source 15 connected in series thereto, operation mode of said source allowing the input voltage polarity to change and, consequently, provides the possibility of changing of potential at point 13 in the course of operation. Registering instrument 16, e.g. a two-beam oscilloscope, allows the possibility of simultaneous measurement of voltage at point 13 and point 17, i.e. measurement of the input voltage in converter 8 in a corresponding phase. Impulse generator 20 or harmonic oscillation generator 21 can be alternately connected to primary winding 18 using switch 19. Further, the circuit provides for blocking of load 14 by capacitor 22.

FIG. 8 illustrates the second version of operation of converter 8 in the mode of signal frequency-conversion. Converter 8 is connected to output of summer 23 of harmonic signals, Direct voltage source 15, via load 14 and choke 25, is also connected to input of converter 8. Registering instrument 16 registers the intermediate frequency voltage at point 13; the action of harmonic oscillations being blocked by capacitor 22.

Operation of said electric signal converter is explained below referring to FIGS. 7 and 8.

First, considered is the circuit shown in FIG. 7, which circuit can be used both for the mode of linear detection of signals, and for the mode of their frequency-conversion.

For the reason that converter 8 and balancing resistor 12 have equal value of resistance, then in any functional relationship U(t) of the input signal, that acts upon primary winding 18 of transformer 9, said signal is electrically neutralised at point 13, and registering instrument 16 can indicate only the value of voltage U_(o), caused by action of controllable direct current source 15, and indicate appearance of the efficient electromotive force in converter 8, i.e. value U'(t). When switch 19 is connected to harmonic oscillation generator 21 in secondary winding 11 at point 17, the operating voltage will be: U_(i)(t)=U_(i) sinω₁t (FIG. 9 a). When the output voltage of controllable source 15 is zero, value U_(o) at point 13 is zero as well, and registering instrument 16 indicates the absence of any signals (FIG. 9 b). When U_(o) grows from zero to U_(max), then instrument 16 registers at point 13 the combined value of U_(o) and that of the converted signal U'(t), the latter representing the result of half-wave detection of signal U_(i)(t)—under the condition of maintaining of the linear dependence of U'(t) both on value of the convertible signal U_(i)(t) itself and value U_(o), in this case—the converting signal, and that being in the phase that corresponds to polarity U_(o) (FIGS. 9 c and 9 d), i.e. in strict conformance with expression (7).

The energy relationship of the signals that act upon converter 8 can be inferred from expression (7). If P'(t) is instantaneous value of the power developed by the efficient electromotive force, then it follows from expression (7) that: P'(t)=α|U ₁(t)|U _(o) ² ÷α|U _(o) |U ₁ ²(t)   (8) where α=γix_(o)l ρ

Expression (8) represents the process of energy interchange between U₁(t) and U_(o), wherein it is obvious that when U_(o)>>U₁, then power P'(t) of the converted signal U'(t) is realised mainly due to signal U_(o),i.e. energy is taken off from the direct current source. This process is illustrated in FIGS. 9 c and 9 d that show that at point 13, i.e. across the load 14 resistance, the function representing the differential relation between voltage U'(t) and current 1, that flows through load 14, has the negative slope: ΔU'(t)/Δ1<0   (9)

Schematic diagrams of the course of electrodynamic processes taking place in converter 8 are shown in FIG. 10: in case when primary winding 18 of transformer 9 is subjected to impulse signals from generator 20. The complete conformity of the pattern of voltages, registered by instrument 16 at point 13, with basic expression (7) is obvious.

When the load 14 resistance is blocked by capacitor 22 having nominal value C, and when the condition 1/ω₁C<<R_(id) is complied with, then at point 13 instrument 16 registers the voltage of the de component of signals U'(t) shown in diagrams in FIGS. 9 c and 9 d (FIGS. 11 a-e), i.e. it registers that linear detection of high-frequency oscillations, with extraction of the modulating function in the proportions in accordance with expression (7). FIG. 11 a shows signal U₁(t) in three versions of its amplitude values: A, 2A, 3A. Accordingly, the converted signal (FIG. 11 b, c, d) is represented in the form of the modulating function having minimal amplitude B, when U_(o)=U_(omax).

In the case when at input of the circuit shown in FIG. 7 a complex periodic signal exist, e.g, sum of two harmonic oscillations U₁ sinω₁ ₂ +U₂sinω₂ ₁ then—the condition of U_(o)>>|U₁+U₂| being maintained —instrument 16 at point 17 will register voltage of beats U₁(t) and U₂(t) (FIG. 12 b), and at point 13 it will register the converted signal U'(t) in the form of the linear detection of theses beats (FIG. 12 b). If R_(id)—resistor 14 is blocked by capacitor 22 (capacity C) and the condition 1/ω₁C<<R_(id) 1/(ω₁−ω₂)>>R_(id) is fulfilled, then voltage at point 13 represents the converted signal U'_(cd)(t) in the form of harmonic function U'_(cd) sin (ω₁−ω₂)t, i.e. the signal of the lower intermediate frequency (FIG. 12 c).

If in the circuit according to FIG. 7, balancing resistor 12 is replaced with second converter 8, then signal of the efficient electromotive force U'(t) at point 13, under the condition U₁(t)=U₁sinω₁t, will be registered by instrument 16, as shown in FIG. 13. Hence, the linear full-wave detection of U₁(t)—the signal at point 17—takes place. In this case, power of the converted signal grows during the period of action of U₁(t) in all above-mentioned versions of usage of the circuit shown in FIG. 7.

Operation of converter 8 in the circuit according to FIG.8 corresponds to the mode of the signal frequency-detection mode. At least two signals are supplied to input of summer 23: data carrier U₂(t)=U₁ sinω₁t and heterodyne signal U₂(t)=U₂ sinω₂ t; that being in the case when amplitude U₁ can vary within a range of values, the condition of U₂≧U_(1max) must be met. When inductance L of choke 24 satisfies the condition ωL>>p, where ω is the lower value of frequency of the acting signals; and blocking capacitor 22 is selected according to the ratio 1/ω_(int) C<<R_(id), where R_(id) is load 14, ω_(int) is the lower value of the intermediate frequency, then in application of the converting signal U_(o) (Uo>UΣ), where UΣ is the combined amplitude of the harmonic oscillations that act on converter 8, instrument 16 at point 13 will register signal U'_(int)(t)=U_(int) sin (ω₂−ω₁)t, where U_(int) is amplitude of the intermediate frequency signal ω_(int)=ω₂−ω₁ (FIG. 12 c).

It is noted that according to expression (1), harmonic signal U_(h)sin(ω₂/2)t can be selected as the converting signal. In this case source 15 is absent, but the condition U_(h)>>U_(t), is satisfied, i.e. U_(h)(t) simultaneously plays the role of the heterodyne signal and converting signal. All remaining signals applied to summer 23 are convertible. Signal U_(h)(t) can act on input of summer 23 or directly on converter 8.

Now the ratios determining the possible optimal values of the signal conversion ratios in converter i must be found.

It follows from ratio (7) that η=

U'(t)/

U   (10) where η is conversion ratio, U(t) is convertible signal.

Thus it follows from expression (7) that: |η|=(2γR _(x) U _(o))/(x _(o) l)   (11)

Expression (11) does not define limits of value η. But for the reason that converter 8 is a two-terminal device, then it can be concluded from examination of the circuits shown in FIGS. 7 and 8 and diagrams represented in FIGS. 9, 12 and 13 that the efficient electromotive force acts in antiphase with respect to U(t) on input of the device, i.e. a deep (100%) negative inverse relation is present, which relation also lowers the converter's input resistance.

Gain of a device having negative inverse relation K_(inv.rel) is known to be determined as follows: K_(inv.rel) =K/(1+βK)   (12) where β is inverse relation coefficient, K is gain of a given device when β=0. In the examined case of estimation of value η for converter 8, the operating, i.e. the actual conversion coefficient η_(set) is associated with physical coefficient η (see expression (11)) according to the following ratio: η_(set)=η/(1+η)   (13) because in any method of connection of converter 8: β=1

For the linear detection mode, transmission coefficient G of converter 8 will be expressed as G=(R _(id)η_(net))/ρ  (14)

Expression (13) demonstrates that the objective to design two-terminal converters 8 is reduced to conformance with the condition η≧1, i.e. (2γ|Rx|U)/(x _(o) l)≧1   (15)

It should be noted that the higher is value of η, the more pronounced is manifestation of the self-matching process of converter 8 with wave-impedance of channel of relaying input signals U(t).

For estimation of noise factor of converter 8, it should be noted that expression (7) is true only when the action of external signals U(t) is the issue. Therefore, the “internal” electromotive force of the converter 8 conductor noise acts upon the converter proper only in the form of the external voltage developed across load 14 and at input of the converter, i.e. developed in the wave-impedance of the signal U(t) relaying channel. Thus, the noise power of converter 8 influences the process of conversion of signal U(t) only to the extent that is provided by a voltage divider R_(inp)/ρ, R_(id)/ρ, where ρ is value of resistance of converter 8, R_(inp) is input resistance of the conversion circuit, R_(id) is resistance of load 14.

It should be noted that in the above-described ratios, that characterise operation of converter 8, such parameter as specific conductance σ of the conductor material is not included. Nonetheless, this parameter must be taken into account, because together with the geometric parameters: x_(o), l and a (for film resistors) said parameter determines magnitude of a predetermined value of ρ, that is resistance of converter 8. Values of l being small, it will be, obviously, easier to obtain the required value of ρ than in the case when materials having a low value of σ are used.

For the reason that value of converting signal U_(o) is comprised by expression (15) as the parameter determining the conversion efficiency, the maximal permitted value U in design of converter 8 should be determined. The limiting factor, that influences selection of σ of a material and values of Uo (apart from the requirement to maintain the thermal balance), is the possible appearance of the non-linear dependence of the converter's material conductive properties on the nature of interrelationship of its physical and geometric parameters. When values of l and x_(o) are low, then in the two-terminal devices manufactured of the materials having a great value of R_(x), the effect of non-linearity of its volt-amper characteristic I=U³ manifests itself, where U is sum of the voltages acting on the converter. The relevant conversion ratio, η_(nonlin), caused by said non-linearity of the l(U) dependence, can be expressed as follows: η_(nonlin) =k(σR _(x) ² U ²)/x _(o) l ²   (16) where k is dimension factor. It is obvious from (16) that η_(nonlin) becomes lower as σ of the material and maximum value of U_(max) acting upon the converter decrease.

The conversion process according to (16) affects operation of the converter in the mode of the linear detection of signals. In the case when the converter performs the frequency conversion, the conversion mode according to (16) provides an additional increase in the converted signal power owing to distribution of the converted input signal's power in channels of the upper and lower intermediate frequencies.

The author has conducted the experimental trial of the converter according to the invention; under the conditions of comparative estimate of the ultimate sensitivity of receiving radio devices within the range of 1GGz÷6 GGz and using the known crystalline mixers, having the least noise coefficient, and the claimed converter as the converting devices at input of the receiving path. The attained gain is 6÷7 dB.

In view of the relative ease of the technique for manufacturing the converter according to the invention in respect of production of semiconductor elements, the proposed invention, aside from the merely technical advantages offers a certain economic gain. 

1-27. (canceled)
 28. An electric signal converter comprising: a converting element, in the form of a two-terminal device, made of a conductive material intended for being supplied with at least two input signals and for extracting a converted signal, wherein a relation between physical parameters and geometric parameters of the converting element and a sum of voltages of the input signals satisfies following condition: 2γ|R _(x) |U/x ₀ l≧1, where U is the sum of the voltages of the input signals, R_(x) is Hall coefficient of the conductive material of the converting element, (C/m³); l is a length of the converting element along a current direction, (m); x₀ is a least one of linear dimensions of the converting element cross section that is perpendicular to a direction of a current flowing therein, (m); γ=τ·ε₀, ε₀ is an electric constant, ε₀≈10⁻¹¹ C/V·m, τ is a dimensionless factor that represents a degree of interrelationship of fields produced in the conductive material by the input signals.
 29. The converter according to claim 28, wherein the voltage of at least one of the input signals is considerably greater than that of each of the other input signals, said at least one input signal of the considerably greater voltage being a converting signal, and the other input signals being signals to be converted.
 30. The converter according to claim 28, wherein the converting element comprises a dielectric substrate; a thin film having a thickness x₀ disposed on said dielectric substrate; and leads disposed in a plane of said film at the distance l.
 31. The converter according to claim 28, wherein the converting element is implemented in a form of a cylinder having a radius x₀ and a length l, provided with leads connected to ends of the cylinder.
 32. The converter according to claim 28, wherein the converting element is implemented in a form of a fine-grained structure having linear dimensions of a grain of an order of x₀, l provided with leads to provide a contact with at least one grain.
 33. The converter according to claim 32, further comprising a substrate, wherein said fine-grained structure is disposed on said substrate.
 34. The converter according to claim 33, wherein said substrate being one of the leads, the other lead directly contacting said grain and having a contact area whose linear dimensions are of the order of those of the grain.
 35. The converter according to claim 28, wherein the converting element is implemented in a form of at least one micro-asperity on a surface of said conductive material, said at least one micro-asperity having a height l and a cross-section size x₀, and said converting element further comprises a lead connected to a micro-asperity apex.
 36. The converter according to claim 28, wherein said conductive material is a material with a high value of Hall coefficient.
 37. The converter according to claim 28, wherein the factor τ being within a range of 10⁻÷10⁻².
 38. A method for converting electrical signals, comprising the steps of: providing a converting element in a form of a two-terminal device made of a conductive material; applying at least two input signals to said converting element; converting said input signals by providing interaction of fields of said signals in the converting element material, which interaction is accompanied by energy interchange resulting in producing an effective electromotive force of converting; and extracting a converted signal that satisfies following relation: ${U^{\prime}(t)} = \frac{{- \gamma}{{R_{x}\left\{ {{\sum{{U_{i}(t)} \cdot {{U_{0}(t)}}}} + {{U_{0}(t)} \cdot {{\sum{U_{i}(t)}}}}} \right\}}}}{x_{0}l}$ where U'(t) is an effective electromotive force across the converting element caused by an action of input signal voltages; R_(x) is Hall coefficient of the conductive material of the converting element, (C/m³); l is a length of the converting element along a current direction, (m); x₀ is a least one of linear dimensions of a converting element cross-section that is perpendicular to a direction of a current flowing therein, (m); γ=τ·ε₀, ε₀ is an electric constant, ε₀≈10⁻¹¹ C/V·m, τ is a dimensionless factor that represents a degree of interrelationship of fields produced in the conductive material by the input signals; Σ U_(i)(t), where i=1, . . . , n, is a combined voltage of the input signals to be converted; U₀(t) is a voltage of an input converting signal; wherein a relation between physical parameters and geometric parameters of the converting element and the sum of the voltages of the input signals is selected according to a following condition: (2γ|R _(x) |U)/(x₀l)≧1, where U is a voltage across the converting element, equal to the sum of the voltages of the input signals.
 39. The method according to claim 38, wherein the voltage U₀(t) of the input converting signal is selected to be significantly greater than the voltage of each of the input signals to be converted, for providing a power of the converted signal by power take-off from the input converting signal.
 40. The method according to claim 38, wherein extracting of the converted signal is performed by an intermediate frequency filter.
 41. The method according to claim 38, wherein extracting of the converted signals is performed by a full-wave circuit through compensation of the combined voltage Σ U_(i)(t) of the input signals to be converted at an electric neutral point of said circuit.
 42. The method according to claim 38, wherein to obtain the converted signal having a low value of an intermediate frequency, the input converting signal is selected as a harmonic signal U₀(t) having a frequency proximate to a half of a frequency of the input signal to be converted.
 43. The method according to claim 38, wherein the voltage U₀(t) of the input converting signal is selected as a voltage of a direct current source; thereby converting of the input signals is carried out in a linear detection mode.
 44. The method according to claim 38, wherein the factor τ being within a range of 10⁻³÷10⁻². 